An asymmetric half-bridge converter is provided. The asymmetric half-bridge converter includes a switch circuit, a resonance tank, a current sensor, and a controller. The current sensor senses a waveform of a resonance current flowing through the resonance tank to generate a sensing result. The controller determines the sensing result. When the sensing result indicates that an ending current value of a primary resonance waveform of the resonance current is greater than a predetermined value, the controller performs a first switching operation on the switch circuit. When the sensing result indicates that the ending current value of the primary resonance waveform is less than or equal to the predetermined value, the controller performs a second switching operation on the switch circuit.
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1. An asymmetric half-bridge converter, comprising:
a switch circuit comprising an upper arm switch and a lower arm switch, wherein the upper arm switch and the lower arm switch are connected to a connection node;
a resonance tank coupled between the connection node and a ground end;
a current sensor coupled to the resonance tank and configured to sense a waveform of a resonance current flowing through the resonance tank to generate a sensing result, wherein the waveform of the resonance current responds to a load condition; and
a controller coupled to the resonance tank and the switch circuit and configured to:
determine the sensing result,
in response to the sensing result indicating that an ending current value of a primary resonance waveform of the resonance current is greater than a predetermined value, perform a first switching operation on the switch circuit,
and in response to the sensing result indicating that the ending current value of the primary resonance waveform is less than or equal to the predetermined value, perform a second switching operation on the switch circuit.
2. The asymmetric half-bridge converter according to
the controller performs the first switching operation on the switch circuit so that the asymmetric half-bridge converter is applied in a light load state, and
the controller performs the second switching operation on the switch circuit so that the asymmetric half-bridge converter is applied in a heavy load state.
3. The asymmetric half-bridge converter according to
the primary resonance waveform is a first resonance undulation in a period when the lower arm switch is turned on, and
the primary resonance waveform ends at the ending current value.
4. The asymmetric half-bridge converter according to
5. The asymmetric half-bridge converter according to
6. The asymmetric half-bridge converter according to
in the first switching operation, the controller controls a current value of the resonance current to be approximately 0 at a first time point when the lower arm switch is turned off and turns on the upper arm switch at a second time point, and
the second time point is behind the first time point by a predetermined length of time.
7. The asymmetric half-bridge converter according to
8. The asymmetric half-bridge converter according to
9. The asymmetric half-bridge converter according to
a resonance inductor, wherein a first end of the resonance inductor is coupled to the connection node;
a magnetizing inductor, wherein a first end of the magnetizing inductor is coupled to a second end of the resonance inductor; and
a resonance capacitor, wherein a first end of the resonance capacitor is coupled to a second end of the magnetizing inductor, and a second end of the resonance capacitor is coupled to the ground end.
10. The asymmetric half-bridge converter according to
11. The asymmetric half-bridge converter according to
12. The asymmetric half-bridge converter according to
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This application claims the priority benefit of Taiwan application serial no. 111105523, filed on Feb. 16, 2022. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
The disclosure relates to a power converter, and in particular, to an asymmetric half-bridge converter.
An asymmetrical half-bridge (AHB) converter provides favorable power conversion efficiency in a conventional AC-DC conversion structure. However, to maintain the same operation, the conversion efficiency of the AHB converter may be affected under different load conditions. Therefore, how to provide the suitable operation of the AHB converter under different load conditions is a research focus for those skilled in the art.
The disclosure is directed to an asymmetric half-bridge converter capable of providing a suitable operation under different load conditions.
An asymmetric half-bridge converter of the disclosure includes a switch circuit, a resonance tank, a current sensor, and a controller. The switch circuit includes an upper arm switch and a lower arm switch. The upper arm switch and the lower arm switch are connected to a connection node. The resonance tank is coupled between the connection node and a ground end. The current sensor is coupled to the resonance tank. The current sensor senses a waveform of a resonance current flowing through the resonance tank to generate a sensing result. The waveform of the resonance current responds to a load condition. The controller is coupled to the resonance tank and the switch circuit. The controller determines the sensing result. When the sensing result indicates that an ending current value of a primary resonance waveform of the resonance current is greater than a predetermined value, the controller performs a first switching operation on the switch circuit. When the sensing result indicates that the ending current value of the primary resonance waveform is less than or equal to the predetermined value, the controller performs a second switching operation on the switch circuit.
Based on the above, the current sensor senses the waveform of the resonance current flowing through the resonance tank to generate the sensing result. When the sensing result indicates that the ending current value of the primary resonance waveform of the resonance current is greater than the predetermined value, the controller performs the first switching operation on the switch circuit. When the sensing result indicates that the ending current value of the primary resonance waveform is less than or equal to the predetermined value, the controller performs the second switching operation on the switch circuit. As a result, the asymmetric half-bridge converter of the disclosure may perform a switching operation corresponding to the waveform according to the waveform of the resonance current. In this way, the asymmetric half-bridge converter may automatically and instantly adopt the corresponding suitable operation under the different load conditions.
In order to make the aforementioned features and advantages of the disclosure comprehensible, embodiments accompanied with drawings are described in detail below.
Some embodiments of the disclosure accompanied with the drawings will now be described in detail. In the reference numerals recited in description below, the same reference numerals shown in different drawings will be regarded as the same or similar elements. These embodiments are only a part of the disclosure and do not disclose all possible implementations of the disclosure. To be more precise, these embodiments are only examples of the appended claims of the disclosure.
Referring to
In the embodiment, the resonance tank 120 is coupled between the connection node ND and the ground end GND1. The current sensor 130 is coupled to the resonance tank 120. The current sensor 130 senses a waveform WF of a resonance current IR flowing through the resonance tank 120. The current sensor 130 generates a sensing result SR based on the waveform WF of the resonance current IR. The waveform WF of the resonance current IR responds to a current load condition.
In the embodiment, the controller 140 is coupled to the resonance tank 120 and the switch circuit 110. The controller 140 may determine the sensing result SR. The controller 140 may perform a switching operation corresponding to the waveform WF of the resonance current IR on the switch circuit 110 based on the waveform WF of the resonance current IR. When the sensing result SR indicates that an ending current value of the primary resonance waveform WF of the resonance current IR is greater than a predetermined value DV, the controller 140 performs a first switching operation on the switch circuit 110. When the sensing result SR indicates that the ending current value of the primary resonance waveform WF is less than or equal to the predetermined value DV, the controller 140 performs a second switching operation on the switch circuit 110. In the embodiment, the first switching operation and the second switching operation respectively correspond to different load modes.
It is worth noting that the AHB converter 100 may perform the switching operation corresponding to the waveform WF according to the waveform WF of the resonance current IR. In this way, the AHB converter 100 may automatically and instantly adopt the corresponding suitable operation under different load conditions.
The implementation details of the first switching operation are described with examples. Referring to
For example, the predetermined value DV is set to be 0.1 amperes. When it is determined that the ending current value I1 of the primary resonance waveform WIR1 is greater than 0.1 amperes, the controller 140 performs the first switching operation on the switch circuit 110 so that the AHB converter 100 is applied in the light load state.
In the first switching operation, the controller 140 controls a current value of the resonance current IR to be approximately 0 (i.e. the current value is I0) at the time point t1 when the lower arm switch ML is turned off. The controller 140 turns on the upper arm switch MH at a time point t2. The time point t2 is behind the time point t1 by a predetermined length of time td. In this way, during the period of the predetermined length of time td, the current value of the resonance current IR is controlled to be approximately 0. Hence, the AHB converter 100 enters a burst mode. In the burst mode, power consumption of the AHB converter 100 may be reduced.
In the embodiment, the waveform WF1 of the resonance current IR may be differentiated to obtain a change in the slope of the resonance current IR. As time elapses, when the sensing result SR indicates that a first decreasing negative slope appears on the resonance current IR and a positive slope subsequently appears, it is determined that the primary resonance waveform WIR1 of the resonance current IR appears. Hence, the controller 140 may determine the time when the primary resonance waveform WIR1 of the resonance current IR appears based on the change in the slope of the resonance current IR. In addition, a current value when the positive slope turns into the negative slope is the ending current value I1. That is, the controller 140 may further determine an ending time point of the primary resonance waveform WIR1 based on the change in the slope of the resonance current IR and obtain the ending current value I1 based on the current value at the ending time point of the primary resonance waveform WIR1.
In the embodiment, the controller 140 may further perform auxiliary determination according to a secondary resonance waveform WIR2 following the primary resonance waveform WIR1. When the sensing result SR indicates that the secondary resonance waveform WIR2 appears after the primary resonance waveform WIR1 of the resonance current IR ends, the controller 140 performs the first switching operation on the switch circuit 110. In the embodiment, the controller 140 may determine whether the secondary resonance waveform WIR2 of the waveform WF1 of the resonance current IR appears by using a slope change of a second decreasing negative slope and a subsequent positive slope.
The implementation details of the second switching operation are described with examples. Referring to
For example, the predetermined value DV is set to be 0.1 amperes. When it is determined that the ending current value of the primary resonance waveform WIR1 is less than or equal to the predetermined value, the controller 140 performs the second switching operation on the switch circuit 110 so that the AHB converter 100 is applied in the heavy load state.
In the second switching operation, the controller controls the current value of the resonance current IR to be a negative current value at the time point t1 when the lower arm switch ML is turned off and instantly turns on the upper arm switch MH at the time point t1 when the lower arm switch is turned off. Hence, the AHB converter 100 enters a continuous mode or a boundary mode. Compared to the burst mode, the output power may be increased in the continuous mode.
It is worth noting that in the second switching operation, the current value of the resonance current IR is controlled to be the negative current value at the time point t1. The negative current value may cause the AHB converter 100 to perform zero voltage switching (ZVS) so that the conversion efficiency of the continuous mode is enhanced.
In the embodiment, the controller 140 may further perform auxiliary determination according to a secondary resonance waveform following the primary resonance waveform WIR1. When the sensing result SR indicates that the secondary resonance waveform of the resonance current IR does not appear, the controller 140 performs the second switching operation on the switch circuit 110.
Returning to the embodiment of
Referring to
For the implementation of the switch circuit 210, the resonance tank 220, the controller 240, the transformer TR, and the output circuit 250 of the embodiment, the embodiments of
Referring to
For the implementation of the switch circuit 310, the resonance tank 320, the controller 340, the transformer TR, and the output circuit 350 of the embodiment, the embodiments of
Referring to
Referring to
For the implementation of the switch circuit 410, the resonance tank 420, the controller 440, the transformer TR, and the output circuit 450 of the embodiment, the embodiments of
In summary of the above, the AHB converter of the disclosure includes the switch circuit, the resonance tank, the current sensor, and the controller. The current sensor senses the waveform of the resonance current flowing through the resonance tank to generate the sensing result. When the sensing result indicates that the ending current value when the primary resonance waveform of the resonance current ends is greater than the predetermined value, the controller performs the first switching operation on the switch circuit. When the sensing result indicates that the ending current value of the primary resonance waveform is less than or equal to the predetermined value, the controller performs the second switching operation on the switch circuit. As a result, the AHB converter may perform the switching operation corresponding to the waveform according to the waveform of the resonance current. In this way, the AHB converter may automatically and instantly adopt the corresponding suitable operation under the different load conditions.
Although the disclosure has been described with reference to the above embodiments, they are not intended to limit the disclosure. It will be apparent to one of ordinary skill in the art that modifications to the described embodiments may be made without departing from the spirit and the scope of the disclosure. Accordingly, the scope of the disclosure will be defined by the attached claims and their equivalents and not by the above detailed descriptions.
Chen, Yueh-Chang, Huang, Tzu-Chi, Meng, Che-Hao, Chiu, Chao-Chang, Fang, Kuan-Chun
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